Remote control system



Aug-4,1941 C. s. sNAvELY Em. 2,292,245

REMOTE CONTROL SYSTEM Filed Nov. 23, 1940 8 Sheets-Sheet2 INVENTORS C'lazeneessnavely AMpedRMz'uepana BY 412% pkel.

' 2119a OR NEY e g- 4, 1942- 'c. s. SNAVELY .ET'AL 45 REMOTE CONTROL SYSTEM Filed Nov. 23, 1940 8 Sheets-Sheet 3 INVENTORS 2729i! ATTORNEY gc. s. SNAVELY ETAL 2,292,245

REMOTE CONTROL SYSTEM Filed Nov. 23, 1940 8 Sheets-Sheet 5 INVENTORS Caz/Pace $.Srzauely AliIedB.Mg;Z6epand BY Arthur" .JdO/iel I 772917 ATTORNEY- Aug. 4, 1942..

c. s. SNAVELY ET AL REMOTE CONTROL SYSTEM Filei Nov. 23, 1940 8 Sheets-Sheet 7 Ta I Fig. 5A.

ug- 4, 1942- t c. s. ISNAVELY ET AL REMOTE CONTROL SYSTEM Filed Nov. 23, 1940 8 Sheets-Sheet 8 F7' 1 Jim 211 I 7' 1! K d 3 w W a j 1 b INVENTORS Cdmvzzeeisrzmlg Alfred 3.1 15219! add BY AmbwRJaekel.

T/zez'r ATTORNEY Patented Aug. 4, 1942 REMOTE CONTROL SYSTEM Clarence S. Snavely, Churchill, Alfred B. Miller, Edgewood, and Arthur P. Jackel, Wilkinsburg, Pa., assignors to The Union Switch and Signal Company, Pennsylvania Swissvale, Pa.,

a corporation of Application November 23, 1940, Serial No. 366,874

26 Claims.

Our invention relates to remote control systems for the control from a central point of selected devices located at remote points, and for also indicating at the control point the condition of such devices and other devices at remote points. In its specific embodiment, our invention relates to centralized trafiic control systems for railroads of the type in which a large number of railway signals and track switches at different stations along the track are controlled from time to time from a dispatchers oifice over a single line circuit, and in which the same line circuit is also employed at other times to indicate the positions assumed by the switches and signals and also to indicate the presence of trains at the same or at other field stations.

Our invention comprises a code signaling system employing a single normally closed line circuit which is controlled by independently operable code transmitters located at the offic and at each of a plurality of field stations. The apparatus is so arranged that the transmission of a code can be initiated only when the line is in its normal closed condition and energized by current of a given relative polarity. To transmit a code, the line is first opened and then a series of short and long impulses of current of the reverse polarity is transmitted, and finally, current of normal polarity is again supplied to the line to mark the end of a code. Thus in a series of codes, the successive impulses of each code are all of the reverse polarity but the codes are spaced by short impulses of normal polarity.

One object of our invention relates to the provision of a relatively simple and reliable all-relay code signaling system which is adapted to perform a large number of different operations with accuracy at a relatively high speed, and which provides the maximum flexibility and economy in its application to difierent installations, both from the standpoint of the physical layout of the territory controlled and the number and grouping of the controlled functions at the different stations.

Our invention is an improvement upon that disclosed in our prior Patent No. 2,183,155, granted December 12, 1939, and upon those disclosed in the copending applications, Serial No. 222,860, filed August 3, 1938, and Serial No. 223,287, filed August 5, 1938, by Snavely and Miller, for Remote control systems.

One feature of our invention resides in an improved organization of circuits in which a single relay checks the integrity of a plurality of circuits which govern the operations of the apparatus on the different steps to insure proper operation during each step of the code, and also during the intervals between steps. Another feature of our invention resides in improved arrangements for operating a series of stepping relays and for generating and selectively receiving long and short impulses constituting a code.

A further feature of our invention resides in an arrangement for equalizing the use of the line between the differentstations by preventing any station from transmitting more than one code if another station has a code stored for transmission, Which is an improvement upon the apparatus provided for a generally similar purpose in the systems of the Snavely and Miller applications above referred to.

Our apparatus also includes circuit arrangements for electrically interlocking the switch and signal levers at the control office, which is an improvement upon the corresponding arrangement of the above-mentioned patent.

A specific feature of our invention comprises means for preventing a signal which has been put to stop by a train from being cleared again inadvertently, as the result of the repetition of a control code under certain conditions.

Other objects and features of our invention will become apparent as the description proceeds.

We shall describe one form of apparatus embodying our invention, and two modifications thereof, and shall then point out the novel features thereof in claims.

In the accompanying drawings, Figs. 1A, 1B, 10, 2A, 2B and 20, inclusive, form a diagrammatic View illustrating in condensed form one arrangement of apparatus employed in a centralized traffic control system embodying our invention. More particularly, Figs. 1A, 1B and 1C, taken together, comprise the dispatchers ofiice equipment for generating and delivering codes to the line circuit for transmission to one station, and for receiving codes from that station and operating the appropriate indication devices of the corresponding office panel. As hereinafter explained in detail, this apparatus may be readily expanded by duplicating certain portions so that it may be used to controland indicate apparatus at any desired number of difierent stations. When the codes include five station selecting steps, as hereinillustrated, the maximum capacity of the system is thirty-two stations and the ofilce equipment will include, as a maximum, thirty-two individual panels each generally similar to the one shown in Fig. 10. Figs. 2A, 2B and 2C, taken together, comprise the equipment at one field station, as arranged for governing train movements over the track layout of Fig. 20, which comprises one end of a passing siding on a single track railroad. In an installation of this character, it is to be understood that the coding equipment at all the stations is generally similar, while in other installations, more particularly those on a multiple track road, it will vary in the number of devices to be controlled and indicated from station to station. In any case, the different stations are distinguished by an appropriate arrangement of jumper connections, so that each is adapted to send and receive a particular code call characteristic of the station, and each code has the number of steps required by the devices at the corresponding station. Fig. 3A shows a track plan for a typical interlocking track layout on a multiple track layout, while Fig. 3B illustrates the special ofiice circuits for controlling such a layout, comprising a modification of Fig. 10. Fig. 4 shows the line circuit connecting the office and stations. Fig. 5A shows a modification of the circuits for the signal lever 2SG which may be used in place of the corresponding circuits of Fig. 10. Fig. 5B shows a corresponding modification of the field stations circuits of Fig. 2C, for use in connection with the apparatus of Fig. 5A.

Similar reference characters refer to similar parts in the several views.

Before proceeding with a detailed description of the circuits, we shall briefly explain the general plan and organization of our apparatus.

In the specific embodiment of our invention herein illustrated, each control code consists of a series of twelve long and short impulses, all of the same polarity, while each indication code has fifteen such impulses, the impulses being spaced by uniformly short intervals of no current. The first impulse of each code is employed to select the direction of transmission, so as to give the ofiice the preference in the use of the line in the event the ofiice and one or more stations initiate codes at the same time. The first impulse is short in each control code initiated at the ofiice, while the first impulse is long in each indication code initiated at a field station. The second impulse is employed to prevent any field station from sending more than one indication code if other stations have codes stored for transmission, in order to prevent undue delay in transmission from any station. The second impulse is long in any indication code transmitted by any station on its first attempt to transmit, and is short in all other indication codes, and is also short in each control code.

The next five impulses (steps three to seven, inclusive) provide thirty-two different combinations of short and long impulses for station selection in case of control codes, or for the selection of the office panel corresponding to the transmitting station in the case of indication codes. Following the station selecting elements a plurality of function impulses are transmitted for governing in turn each of a plurality of controlled devices. Each control code usually includes four function impulses and each indication code seven; sponding to each function impulse is operated in accordance with the long or short character of the impulse, during the line closed period constituting the next succeeding impulse. Each code includes an additional step during which the last function impulse is registered, this final step being the twelfth step in a control code and the the controlled device correfifteenth in an indication code, and is a short impulse in each case.

The apparatus at the office and stations is generally similar and with a few exceptions, which will be pointed out as the description proceeds, corresponding relays at the office and stations operate in unison on each step.

The line circuit, as shown in Fig. 4, includes in series the winding of a positively biased polar line relay Ll, a negatively biased polar line relay L2, and back contacts a and b of a transmitter relay OT at the office and of a similar relay T at each station, and at the ofiice it includes a line battery LB and the contacts a and b of a pole changer relay PC. The line circuit at the office also includes the winding of a neutral line relay L0 and the closed contact of a key 2PB forming a part of a manual stepping device similar to that described in the prior application, Serial No. 223,287, hereinbefore referred to.

Each code is stored for transmission, upon the release of a normally energized starting relay IS or S, (Figs. 13 and 2B) which initiates the code by energizing the associated transmitter relay OT or T to thereby open the line circuit.

Portions of the line circuit are also shown in Figs. 1A and 2A, and it will be clear from Fig. 4 that the portion of the line circuit shown in Fig. 1A, and a plurality of portions, one for each station, each similar to the portion shown in Fig. 2A, are connected by the line wires y and z to form a single closed circuit which is normally energized by current supplied by the office line battery. This current is normally of the proper polarity to cause the relays Ll to be picked up, while the relays L2 which operate only on current of the opposite polarity normally occupy their released positions, as shown. As soon as the line circuit is opened to initiate code transmission, relay PC is operated and the polarity is reversed; each relay Ll remains released for the duration of the code, and the relays L2 are operated repeatedly in unison in accordance with the code generated by the repeated opening and closing of the line circuit by relay OT, in case of a control code, or by one of the relays T, in the case of an indication code.

The pole-changer PC is restored to its normal position during the line-open interval following the last impulse of each code, so that the relays Ll are again energized and pick up and relays L2 are released when the line is restored to normal at the end of a code.

Each relay Ll controls a normally energized relay W and a timing relay Al, in series, which relays are deenergized for the duration of each code.

Each relay L2 controls two series of cascadeconnected timing relays, A2, B2, C2, and A3, B2, C3, (relay B2 being common to both series), the relays of one series or the other being energized successively to generate and to register the long impulses of a code like the similarly designated relays of application Serial No. 223,287. The two series of relays are used alternately. Each timing relay A2 or A3 is picked up over a circuit which includes a winding of a polar relay Z of the magnetic stick type. Relay A2 is energized and relay Z operated to the left at the beginning of each odd-numbered step, while A3 is energized and relay Z operated to the right at the beginning of each even-numbered step. The timing relay which happens to be in its energized position when relay L2 releases at the end of an impulse is held energized over its stick circuit which includes a contact of relay Z and a winding of a polar relay Y of the magnetic stick type. Relay Y is operated to the left at the beginning of the line-open interval following each oddnumbered step, and to the right at the beginning of the interval following each even-numbered step. Relay Y controls the pick-up circuits for relays A2 and A3 to cause these relays to be operated alternately in response to the repeated operation of relay L2. Relay Z similarly controls the stick circuits for these relays so that a relay of the proper series will be held energized during each interval between impulses, and also controls the circuits by which the function elements operate the field stick relays IWS, ZLHS, ZRHS, (Fig. 2C) or relays ITK, ZRAK, etc., (Fig. 1C).

Each of the circuits including relay Y or Z also includes, in series, the winding and front contact a of a checking relay X which relay is held energized for the duration of a code.

Relay X and the timing relays of one series or the other, selected by relay Y, control a series of stepping relays P, 2P, etc. Each relay P is energized upon the operation of relay Y during the interval preceding the corresponding step of the code, is held energized over a stick circuit during the corresponding step, and is released during the following interval after the next P relay picks up.

At the omce, relays HP to IZP, inclusive, Fig. 1B, are thus held energized on steps I to H, respectively, of a control code, and relays iP to 15F on steps I to l5 of an indication code. A station selector relay ID or 2D is picked up in unison H with relay 8P in accordance with the character of the seventh step to effect the control of the switch and signal control relays IWS, ZLHS, etc., of Fig. 20 on succeeding steps in accordance with the positions of the switch and signal levers lSW and ISG, and associated relays of Fig. 10 in the case of a control code, or to effect the control of the indication relays ITK, ZRAK, etc., of the selected panel, in accordance with the positions of the station relays ITR, ZRAR, etc., of Fig. 2G, in the case of an indication code.

At each station, as shown in Fig. 2B, there are two relays for the second step, either relay 2PL or ZPS being picked up according to the long or short character of the first step, and some of the stepping relays are operated through two cycles to reduce the number of relays required. At the selected station, relay ZPS is operated as the next in order after relay lP, in unison with a selector relay D and the oflice relay SP, and then a chain repeat relay CR, of the stick polar type, is reversed, upon the release of relay 1P. During the first cycle, the stations relays 3? to l? are each operated in accordance with the character of the next preceding step, to select the deired station, but when relay CR reverses, the bus-wires by which the station selection is effected are connected together, so that during the second cycle, relays 3P to 1P are operated irrespective of code ch'aracter, in unison with the ofiice relays 9P to I31, respectively, relay MP be ing operated on the ldth step.

All of the groups of relays above mentioned are operated for both transmitting and receiving, diiferentiation between control and indication codes being efiected by the energization of relays OM (Fig. 1A) and B (Fig. 2B) in unison with relays ESP and EPS, in case of a control code, and by the energization of relay OR (Fig, 1B) and ZPL (Fig. 2B) in unison with relay 2P, followed by the energization of relay M (Fig. 2B), in case .of an indication code.

Each control code is initiated by a code sending relay such as ISP (Fig. 1B) which picks up upon the release of the corresponding starting relay is and completes a circuit ill for the transmitter relay OT (Fig. 1A), at its front contact 0. This circuit includes a front contact 1 of relay Al, and hence is available only when the line is supplied with current of normal polarity.

Each indication code is initiated by closing a similar circuit M0 for relay T (Fig. 2A) which is completed upon the closing of back contact 0 of the station starting relay S. During the code,.

each time relay OT or T picks up, the line is opened and the energization of a diflerent stepping relay P results, which relay, in turn, opens the circuit for relay OT or T at a back contact e or 1, so that relay OT or T releases to close the line; the P relay then energized, at its front contact prepares another branch of the circuit for relay OT or T, which is completed, to terminate the impulse, upon the closing of a front contact of relay A2 or A3, in the case of a short step, or upon the closing of back contact f of relay B2, in the case of a long step. In this manner, each transmitter relay is energized repeatedly and selectively to generate the different codes as required.

Referring now to Fig. 10, one feature of our invention is the provision of arrangements for electrically interlocking the oflice control levers such as the switch lever l SW and the signal lever ISG, which is an improvement upon the generally similar arrangements shown in our prior patent hereinbefore referred to. Each switch lever is provided with a polar stick lever repeater such as the relay lPR, having a contact I) for determining the character of the switch control step of the code, a neutral control relay such as lWC for controlling a route circuit governing the transmission of signal control codes, and a polar stick indication relay such as IWK which is reversed upon a movement of the switch lever if conditions permit the transmission of a switch control code and restored to normal upon receipt of a code indicating that the corresponding track switch has assumed a position in accordance with such code.

Each signal lever such as lever ZSG is provided with two neutral control relays such as the relays ZHC and 2N0 for selecting the clear and stop signal controls, respectively, a polar stick relay such as ZPR for selecting the left-hand or right-hand direction when the lever controls si nals governing traffic in opposite directions, together with a signal indication relay such as ZHK which occupies its normal left-hand position as shown when the controlled signals are at stop and is reversed when any of these is cleared, and a lock indication relay ZMK controlled by the approach locking relays associated with the signals.

The object of these interlocking arrangements, as illustrated herein more fully in Fig. 3B, is to insure that a sequence of related codes for controlling the track switches of a route and for clearing the desired signal will be transmitted in the desired order. In the system of our prior patent, this was accomplished, in part, by the employment of an individual control code for each operated device, in lieu of a composite code capable of controlling a pluralit of devices on successive steps, as employed in the system shown herein. In systems of the latter type, it is desirable, under certain circumstances, to avoid the repetition of a code for controlling a signal, that is, it is desirable to send a code for clearing a signal or for putting it to stop only in response to an operation of the corresponding lever. This is accomplished in a novel manner herein by the provision of an additional step in the code, controlled by a signal selecting relay such as 2G0, Fig. 10, which is energized only when the corresponding signal lever ZSG is operated, and which controls a corresponding selecting relay 2G8, Fig. 2B, in the field. The arrangement is such that the signal control impulses corresponding to the position of lever ISG although transmitted, as required for operation of the stepping relays P, are not delivered to the signal control relays ZLHS and ZRHS of Fig. 20, unless the code is initiated as the result of the operation of lever 2SG.

The office control levers shown herein are of a novel type, combining the functions of a spring return starting push button and of a rotatable control lever in a single device. Each lever such as ISW or 2SG, Fig. 1C, is normally locked in its last operated position by a spring actuated detent, and the lever must first be pushed, closing contact a and opening contact I), to disengage the detent. The lever may then be rotated to move its control contacts and d to the desired position, and when released, becomes locked in that position by the actionof the spring, which also effects the opening of contact a and the closing of contact I), the latter contact then completing a circuit for initiating a code containing a control element corresponding to the position of contact 0.

Another feature of our apparatus resides in the provision of an auxiliary lever ZNS associated with lever ZSG, Fig. 1C. In normal operation, with lever 2NS in its left-hand position, the signal remains at stop after a train passes through section It because relays ZLHS and ZRHS, Fig. 2C, are restored to normal by the operation of the track relay ITR and its repeater relay ITZ. If a signal is cleared and lever ZNS operated to the right, a signal clear code will be transmitted automatically upon receipt of a code indicating that a train has caused the signal to assume the stop position, so that the signal will clear again for a following train.

A number of the relays employed in our apparatus are rendered slow release by the connection of asymmetric units of the copper oxide rectifier type in multiple with the relays, as shown conventionally for relay Al or A2, Fig. 1A, for example. These units present a high resistance to the flow of current from the power source while providing a low resistance discharge path to permit the gradual discharge of the stored inductive energy of the relay when the power source becomes disconnected. The stepping relays P and the relays W and X are in this manner arranged to have sufiicient retardation to hold them picked up in each case until other relays have picked up, while the timing relays AI, A2, etc. are arranged to have a definite constant time period which is preferably the same for all of these relays and which is so chosen as to provide the proper rate of operation and to so measure the relative lengths of the different impulses as to insure a wide margin against incorrect operation.

While any suitable relays may be used, the code relays shown herein are preferably of the types shown in the Snavely Patents Nos. 2,140,-

604, issued December 20, 1938, and 2,178,289, issued October 31, 1939, for Electrical relays.

Referring now to Fig. 2C, the-track diagram at the top represents a stretch of railway track including a track switch IW and a group of signals 2B and EL for governing traflic movements over the switch, corresponding to one end of a'passing siding on a single track railway. The circuits of Fig. 20 represent one arrangement of interlocked switch and signal control apparatus which the polar stick relays IWS, 2LHS and 2RHS of our station equipment are adapted to control. As indicated in Fig. 20, the code-responsive relay IWS governs a switch control relay IWZ which in turn controls the switch machine ISM so as to operate the track switch IW to a position to correspond with that of contact a of relay IWZ, when conditions are proper. The switch machine ISM controls a switch indication relay IWP which indicates the position and locked condition of switch IW, and relay IWP controls the normal and reverse indication repeating relays INWP and IRWP, the contacts e and f of which govern the transmission of switch indication codes as hereinafter described, for controlling relay IWK, Fig. 1C.

The signal shown in Fig. 2C are assumed to be of the well-known light signal type and each is controlled by a signal relay G over a circuit controlled by the code controlled relays ZLHS and ZRHS. When all the signals for one direction are at stop, the corresponding signal indication relay LGP or RGP is energized. Each relay GP at its contacts e and f governs the transmission of signal indication codes as hereinafter described for controlling relay 2I-IK, Fig. 1C, and at its contact 0 controls an approach locking stick relay LAS or RAS. The detailed circuits for relays LAS and RAS have been omitted, to simplify the drawings, but these may be arranged, for example, as shown for similarly designated relays in the Young Patent No. 2,141,074, granted December 20, 1938. The approach locking relays together with the track relay ITR for the switch section It control the circuit for relay IWZ and also control a switch locking repeater relay IMP. Relay IMP at its contact a controls the circuit for the code controlled relay IWS and at its contacts 6 and f governs the transmission of codes for controlling relay IMK, Fig. 1C.

Contacts e and f of the track relay ITR and of the approach relays LAR and RAR, Fig. 2C, govern the transmission of track indication codes for the control of the corresponding relays ITK ZRAK and 2LAK, respectively, Fig. 1C, to indicate the condition of the detector track section It and of the adjacent approach sections.

The signal circuits, as shown in Fig. 2C, are so arranged that a signal can be cleared only after the corresponding approach locking relay ZRAS or 2LAS is released, the latter relays being released in response to the operation of the corresponding code controlled relay ZRI-IS or ZLHS, in a manner similar to that described in the Allen et al. Patent No. 2,117,691, granted May 17, 1938. The arrangement shown herein includes an improvement over Allen et al. comprising the addition of a block relay 2BR, which is controlled over the signal line circuits and which prevents the release of the approach locking relay by the code-controlled relay if an attempt is made to clear a signal for an unavailable route.

The transmission of a typical control code will now be described in detail. It will be assumed.

that the apparatus is in the condition shown in the drawings, and that the code is initiated by a movement of the switch lever ISW, Fig. 1C, which controls the track switch IW, from normal to reverse, and that the corresponding five step station code call comprises a short impulse followed by two long impulses, followed in turn by two short impulses.

The starting relay IS, Fig. 1B, for the individual panel of Fig. 1C is normally held energized over a circuit No. 1 which may be traced from one terminal B of a suitable source of current, resistor TI, the lower winding and contact a of relay IS, thence in Fig. 1C over the normally closed contact b of each lever of the corresponding panel to the other terminal C of the source.

Referring now to Fig. 10, when the switch lever ISW is first pressed, its contact I) opens circuit I, releasing relay IS. If conditions in the field are proper for the operation of switch IW, a code indication will have been received to operate relay ZMK to the left, as shown, and if the signal lever ZSG is in its stop position a circuit 2 is closed from terminal B at its contact (2 over the left-hand contact of relay ZMK through relay ZNC to terminal C, so that-relay ZNC is energized, as shown. Under these conditions the initial operation of lever ISW completes a circuit 3 for the stick polar switch correspondence relay IWK from terminal B, contact I) of relay ZNC, the lower winding of relay IWK and contact a of lever ISW to terminal C. Relay IWK is operated to the right over circuit 3, and its left-hand contact a opens a circuit 4 for relay IWC extending to terminal B over the left-hand contacts 0 of relay IPR and lever ISW. Relay IWC releases and opens its contact 0 in a pickup circuit 5 for relay 2H0, thereby rendering lever ZSG ineifective to transmit a signal clear code.

The right-hand contact I) of relay IWK completes a circuit 6 for the switch indication lamp IWE which now becomes lighted, and completes connections to terminal C for circuits Ia and lb for relay IPR extending to terminal B at contact c of lever ISW, relay IPR becoming energized over circuit Ia in the normal direction to corerspond with the position of lever ISW.

Lever ISW is now turned to the right from normal to reverse, relay IPR becoming energized in the reverse direction over circuit lb and closing its right-hand contacts. Relay IPR controls the character of the eighth step of the code in accordance with the position of its contact b, and its contact it prepares a circuit for restoring relay IWK to its left-hand position upon receipt of an indication code indicating that the track switch controlled by lever ISW has assumed a position corresponding to that of relay IPR. Lamp IWE remains lighted until this occurs.

In the. event lever ISW is operated when relay ZNC is not energized, relays IWK and IPR will fail to respond, but relay IWC will be released upon movement of the lever out of correspondence with relay IPR, in which case circuit 6 will be energized from a source of interrupted current F3 to cause lamp IWE to display a flashing indication, warning the operator that a code for operating the switch cannot be issued.

Assuming lamp IWE to be lighted steadily, lever ISW is released in the reverse position, opening contact a and closing contact I), contact 0 becoming locked reversed.

Relays W and AI, Fig. 1A, are normally energized over a circuit 8 extending from terminal B over front contact a of relay LI through the windings of relays W and AI in series to terminal C. The closing of contact 11 of lever ISW therefore completes a circuit 9 from terminal B, front contact 6 of relay W, the upper winding of relay ISP, Fig. 1B, back contact h of relay ID, back contact a of relay IS, and thence over circuit I already traced to terminal C.

Relay ISP picks up over circuit 9 and at its contact 0 completes abranch Inc of an initial energizing circuit ID for the transmitter relay OT, Fig. 1A, extending from terminal B over contact c of relay ISP, back contact 6 of relay ID, back contacts 1 of relays 'IP, 6P, 5P, 4P, 3P, 2P and IP, front contact 1 of relay AI, back contact I) of relay X, through the winding of relay OT to terminal C.

Relay OT picks up over circuit II) to initiate the code, opening the line circuit at its contacts a and b and thereby releasing the line relay LI at the oflice and at each station.

Relay LO. Fig. 4, controlling the manual stepping apparatus, is also released, but this relay performs no useful function during normal operation.

Each line relay LI, upon releasing, opens the pick-up circuit 8 and closes a stick circuit II for relays W and AI extending from terminal B at back contact b of relay LI, contact 0 of relay W, the winding of relay X, contact (1 of relay L2, the lower winding of relay Y, front contact a and winding of relay W and the winding of relay AI to terminal C.

Circuits I I constitute pick-up circuits for relays X which now pick up, and each relay Y is operated to the right over circuit I I.

The ofiice relay LI also closes a circuit I2 from terminal B at its back contact a which extends over contact e of relay Al through the lower winding of the stick polar relay PC, which relay becomes energized to operate its pole-changer contacts a and b to the right, in which position they remain until relay PC is restored to normal at the end of the code.

At the office, Fig. 1A, relay X completes a pick-up circuit I3 for relay IP of Fig. 1B, extending from terminal B at contact 0 of relay X over the right-hand contact I) of relay Y, front contact :1 of relay AI through the winding of relay IP to terminal C. Contact I) of the office relay X opens circuit I0, deenergizing relay OT which then releases to close the line to begin the first code impulse. Each station relay X, Fig. 2A, completes a circuit II3 for the station relay IP, Fig. 2B, which is similar to circuit I3 except that it extends to terminal C through the upper winding of a polar stick chain repeat relay CR which is thereby energized in its normal direction, as shown. Relay IP at the oflice and at each station therefore pick up in unison.

Since relay PC is reversed, the line relays L2 at the ofiice and at each station pick up in unison in response to the closing of the line circuit by relay OT; and each completes a pick-up circuit Ma for relay A2, which is one of a plurality of branches of a circuit I4 for relays X and Z extending from terminal B at contact I) of relay LI, front contact a and winding of relay X, contact a of relay L2, right-hand contact a of relay Y, the upper winding of relay Z, front contact 0 of relay AI, the winding of relay A2 to terminal C. Circuit I4 is a stick circuit for relay X, which is therefore held energized; and the closing of the branch I 4a picks up relay A2 and also operates relay Z to close its left-hand contacts as shown if they are not already in that position.

Each circuit II is now open, and relays W and AI release to remain deenergized for the remainder of the code, the ofice relay W completing a stick circuit I5 from terminal B at its back contact e, contact a and the lower winding of relay 1 SP, back contact I of relay ID to terminal C, over which relay ISP is held energized independently of the condition of circuit I so that the'code in progress cannot be interfered with by lever operation. Relays Al, upon releasing, open the pick-up circuit l3 for relay ii? at the ofilce and the similar circuit M3 for relay IP at each station at their front contacts 11, but relays EP are held energized over the stick circuits i5 and i it, as shown on the drawings.

When the office relay A2 picks up, its contact 1 completes a branch Ila of a circuit Il over which relay OT is controlled to generate the short oddnumbered impulses. Circuit lla extends from terminal B at contact 0 of relay ISP over the same path as for circuit Ita to back contact J of relay 2?, thence over front contacts 1 of relays EP and A2, relay OT to terminal C. Relay OT therefore f picks up and opens the line circuit to terminate the first impulse as soon as relay A2 picks up, releasing the line relays L2.

Each relay L2 upon releasing closes a stick circuit I80, for relay A2, comprising a branch of a circuit I8 for relays X and Y, which may be traced from terminal B, back contact b of relay LI, contact a and winding of relay X, contact b of relay L2, the upper winding of relay Y, back contact b of relay W, left-hand contact b of relay Z, front contact a and winding of relay A 2 to terminal. C. Relay X is held energized and relay Y operated to the left over circuit I8 and the ofiice relay Y completes a circuit Ita to pick up relay 2P extending from terminal B at contact 0 of relay X over left-hand contact b of relay Y, contact I) of relay I]? through relay 2P to terminal C, circuit I9a being a branch of a stick circuit I9 for the even-numbered relays P. At the same time, relay OM is picked up over a circuit 26a which is a branch of a circuit 23 closed only at the end of a short odd-numbered impulse, circuit 28a. being similar to circuit I a except that it includes front contacts at of relays A2 and. HP. At each station, relay I R,'Fig. 2B, is picked up over a circuit I2lla similar tocircuit 28d, and relay 2P3 is picked up over a circuit lZQb which is also similar to circuit Eta except that it includes front contact b of relay IP. Relay 2P it will be seen, is picked up in dependently of code character, but the energizetion of relays OM, lR and ZPS is eiiected only in response to a short first impulse characteristic of a control code. Relay 2P5 is held energized over a stick circuit I is controlled by the left-hand contact b of relay Y and similar to circuit i9, but relays OM and lit are held energized until the code is completed over branches filo and I2 la, respectively, of holding circuits 2! and 52! extending to terminal 13 at back contacts b of the asscciated relays Al.

The opening of right hand contacts I) of relays Y interrupt the stick circuits Iii and lit for the relays IP and these relays release.

The office relay 2P, upon picking up, opens V circuit Ila, releasing relay OT which then closes the line circuit to begin the second impulse.

Relays L2 now pick up again in unison, and each completes a pick-up circuit 22a for relay A3, comprising a branch of a circuit 22 for relays'X and '2 which extends from terminal B at contact b of relay L'I, over contact 'a and winding of relay X, contact a of relay L2, left-hand contact a of relay Y, lower winding of relay Z, front contact 0 of relay A2, relay A3 to terminal C. Each relay X is held energized, and each re lay Z operated to the right over circuit 22. Each relay A3 picks up, and the office relay A3 at its contact 1 completes a branch 23a of a circuit 23 over which relay OT is controlled by relay A3 to make the second step short. Circuit 23a comprises a connection from terminal B over circuit Ita and front contact I of relay 2P to circuit 23 extending to terminal C through relay OT over front contact c of relay OM and front contact ,7 of relay A3. Relay OT becoming energized over circuit 23a, opens the line circuit to terminate the second impulse, releasing the line relays L2,

Each relay L2, upon releasing, closes a holding circuit 24a for the associated relay A3, circuit 24a. being a branch of a circuit 24 for relays X and Y, which may be traced from terminal B at back contact b of relay LI, contact a and winding of relay X, contact (1 of relay L2, lower winding of relay Y, back contact a of relay W, right-hand contact a of relay Z, front contact a of relay A3 to terminal C. Relays X are held energized, and relays Y operated to the right over circuits 24, and the ofiice relayY .com pletes a circuit 25a to .pick up relay 3P, extending from terminal B at contact 0 of relay X over right-hand contact b of relay Y, back contact d of relay AI, contact b of relay 2P, through relay 3P to terminal C. Circuit 25a is a branch of a stick circuit 25 for relay 3P and the remaining odd-numbered P relays. At each station, relay Y completes a similar pick-up circuit 4250, for relay 3P which includes a front contact 1) of relay ZPS, circuit I25a being a branch of a stick circuit I25 for relays 3P, SP and IP. Relays Y also open the stick circuit I9 and I Is for relays ZPand ZPS and these relays release.

The oifice relay 3P, upon picking up, opens circuit 23a, releasing relay OT which then closes the line circuit to begin the third impulse.

It is to be understood that when an installation includes the full complement of 32 stations, there will be two relays 4P at the office, controlled over contacts b and c of relay 3?, two relays it]? for each relay 4P, two relays GP for each relay 5P, and two series of relays 'IP to I'o'P for each relay 6P; that is, there will be sixteen such series, each relay 'IP controlling selector relays 1D and 2D for two stations. Furthermore, the number of relays in each series may be varied as required, according to the number of devices to be controlled.

The apparatus of Fig. 213 may also be varied at different stations according to the number of devices to be controlled. A-single delivery relay D is employed for the control-of a groupof apparatus such as is shown in Fig. 2C, anotherrelay D may be added if the apparatus is equivalent to two such groups; two relays 'IP and 'four relays D may be used for a larger layout, and so on. On the drawings, these variations in the connections for the "windings of the relays P and of their contacts 6 and f are indicated by small circles at certain wire intersections. It is to the understood that a black circle such as that connecting circuits 20 and 250, Fig. 1B, or the one connecting circuits I20 and 1200, Fig. 23, represents a closed connection, and that the'ad- J'acent white circle represents an open connection which may be used either in place of the closed connection or in addition thereto.

Each stepping relay at the transmitting point, controls the length of the code step of corresponding number, relays 3P to IP, inclusive, generating the station code call. Each step of the code begins when the transmitter relay is released due to the opening of back contact e or ,f of the corresponding numbered relay P, and terminates when it is picked up over a circuit closed by a timing relay but including a front contact of the same relay P. Each step is short or long, depending upon whether the transmitter relay picks up over contact 1 of relay A2 or C2, the case of an odd-numbered step, or over a contact 1 of relay A3 or C3, in the case of an even-numbered step. In the case of the short steps, relay T is energized as soon as relay A2 or A3 picks up at the beginning of the step, but to produce long steps of suitable length, the energization of relay T is delayed by including in its circuit the back contact of relay B2. In the code being described, the third step is short because relay OT picks up over a circuit 26a comprising a connection from terminal B over circuit Illa to circuit 26 and thence through relay OT to terminal C. To select a station having a code call in which the third step is long, a connection would be provided from terminal B at the contact of another code sending relay such as relay ZSP over circuit I01) and the front contact f of relay 3P to circuit 29. In this case, relay 4P, which is selectively controlled in accordance with the length of the third step, would be energized over circuit 3!! in place of circuit 20.

When each relay L2 picks up at the beginning of the third step in the code being described, the holding circuit 24a for each relay A3 is opened, but before relay A3 releases the branch Nib of circuit [4 is closed to energize relays A2, Z and X. The closing of circuit M completes a cycle of operation of the relays X and Y which is repeated, with slight variations on the long steps, until the end of the code, circuits M, It, 22 and 24% being closed successively and repeatedly. Each of these circuits constitutes a stick circuit for relay X which thus remains picked up until the end of the code and checks the integrity of these circuits.

When the office relay A2 becomes energized as just described, its contact completes the circuit 26a for relay OT, which relay then picks up to terminate the third impulse, opening the line circuit and releasing the relays L2.

Each relay L2 upon releasing closes circuit I811 to hold relay A2 energized and to operate relay Y to the left, and relays Y close circuits 20c and [200 to pick up relays 4P at the office and at each station for which the code call includes a short third step. Relay Y also opens the holding circuits 25 and I25 for relays 3? at the office and at all stations, no further progression of the P relays occurring at those stations at which a P relay does not pick up at the end of a code step.

At the office, contact 1 of relay lP opens circuit 26a, releasing relay OT to close the line to begin the fourth step, and also prepares a circuit 21a comprising a connection from terminal 13 over circuit Ida and front contact 1 of relay 4P to circuit 21 over which relay OT is controlled to make the fourth step long. Circuit 21 extends through relay OT to terminal C over contact d of relay OM, front contact I of relay C3 and back contact ,f of relay B2.

Relays L2 now pick up, and each opens circuit 3a and closes circuit 220., so that each relay A3 picks up and each relay Z is operated to the right. Each relay A2 is deenergized, and upon releasing, its front contact 0 opens circuit 22a, deenergizing relay A3, and another branch 22b of circuit 22 extending over back contacts 0 of relays A2, C2 and D2, front' contact b of relay A3 and the winding of relay B2 to terminal C is closed to pick up relay B2.

Each relay A3 then releases, and its contact 12 opens branch 22b, deenergizing relay B2, and closes branch 220 including front contact b of relay B2 to pick up relay C3. Each relay B2 then releases and the ofiice relay B2 at its back contact 1 completes circuit 21a for relay OT, which picks up to open the line circuit to terminate the fourth impulse.

Each line relay L2 now releases, and since the relays C3 are now picked up, each relay L2 completes a branch 24b of circuit 24 to hold the associated relay C3 energized. Each relay Y is operated to the right over circuit 24. The office relay 5P is energized over a branch 28a of circuit 28 including front contact (I of relay C3 and contact I) of relay 4?. Relay 5P at each station arranged to receive a long fourth step and also having its relay 4P picked up is energized over a corresponding branch 128a of circuit I28, and the energized relays 4P then release.

When the oflice relay 5? picks up, its contact 7 opens circuit 21a, releasing relay OT to close the line circuit to begin the fifth step, and also prepares a circuit 29a comprising a connection to terminal B over circuit 50a and front contact 1 of relay 5P to circuit 29, over which relay OT is controlled to make the fifth step long. Circuit 29 extends through OT to terminal C over front contacts I of relays OM and C2 and back contact f of relay B2.

Relays L2 now pick up, and each opens circuit 241) and closes the branch Me of circuit M to pick up relay A2 and to operate relay Z to the left. Each relay C3 is deenergized, and upon releasing, its contact 0 opens circuit Me, deenergizing relay A2, and closes circuit Md to pick up relay B2. Each relay A2 then releases, and its contact b opens circuit Md, deenergizing relay B2, and closes circuit Me to pick up relay C2. Each relay B2 then releases, and the office relay B2 at its back contact I completes circuit 29a for relay OT, which picks up to open the line circuit to terminate the fifth step.

Each line relay L2 now releases, and since the relays C2 are now picked up, a stick circuit for each relay C2 comprising the branch lb of circuit l8 becomes closed. Each relay Y is operated to the left over circuit i8, whereupon the oiiice relay SP is energized over a branch 30b of circuit 32 including front contact at of relay C2 and contact I) of relay 5?. Relay 6? at each station arranged to receive a long fifth step and also having its relay 5P picked up is energized over a corresponding branch [30b of circuit I30, and the energized relays 5P then release.

When the office relay 6P picks up, its contact 1 opens circuit 29a, releasing relay OT to close the line to begin the sixth step, and prepares a circuit 231; extending from terminal B over circuit 10a and front contact 1 of relay 6P to circuit 23. Relay CT is controlled over circuit 231) to make the sixth step short.

Relays L2 now pick up, opening each circuit I8?) and closing each circuit 22d to pick up relay A3 and to operate relay Z to the right.

When the oflice relay A3 picks up, its contact ,1 completes circuit 23b for relay OT, which picks up to open the line to terminate the sixth step.

Each line relay L2 now releases, completing the stick circuit 25a for relay A3 and operating relay Y to the right. At the office, relay 5P picks up over a branch 3Ia of circuit .iI including front contact 11 of relay A3, and at one or two stations only, relay 'IP picks up over a corresponding branch I3Ia of circuit I3I.

When the ofiice relay 'IP picks up, its contact 1 opens circuit 23?), releasing relay OT to close the line to begin the seventh step, and prepares a circuit 26b at its front contact I similar to circuit 26a already traced, to make the seventh step short.

Relays L2 now pick up, opening each circuit 24a, and closing each circuit Mb to pick up relay A2 and operate relay Z to the left. Contact f of the office relay A2 completes circuit 26b to cause relay OT to pick up to open the line circuit to terminate the seventh step.

Each line relay L2 now releases, completing the stick circuit Isa for relay A2 and operating relay Y to the left. At the cfice, relay 8? picks up over circuit I5 b including contact b of relay 'IP, and at the same time relay ID picks up over the branch 26d of circuit 29 including contact (1 of relay 'IP to register the short seventh step, and completes a stick circuit Zic over which relay ID is held energized until the end of the code. At the selected station, relay D, Fig. 2B, is picked up over a branch IZfid of circuit I29 which includes the left-hand contact at of relay CR and front contact d of relay 1?, and relay 2P5 is picked up over a branch I2ile of circuit I29 which includes the left-hand contact 1) of relay CR and front contact b of relay 7?. Relays 'EP now release due to the opening of their stick circuits 25 and I25 by relays Y, and upon the release of the relay IP at the selected station, relay CE. is energized over a branch I2Ic of circuit I2I extending from terminal B at contact b of relay AI through the lower winding of relay CR, contact a and winding of relay D to terminal C. Relay CR operates its contacts to the right in response to the energization of circuit 5225c. This circuit also constitutes a stick circuit for relay D, and being connected directly to terminal B at back contact b of relay AI, remains closed until the end of the code. Contact 0 of relay CR connects circuits I23 and I3I together, and the right-hand contact d of relay CR connects circuits I20 and I30 together. This enables the station relays 4P to 'IP to be operated in unison with the office relays IElP to ISP, respectively, on the function steps of the code, irrespective of their code character, but without the necessity for the provision of additional energizing circuits for these relays, as employed for example in the system of the Snavely and Miller application, Serial No. 222,860, hereinbefore referred to.

The apparatus is so arranged that no interference will occur in case levers of other panels are operated during the code or prior to its initiation. The pick-up circuit 9 for all SP relays is opened at the beginning of the code, but it may happen that other SP relays such as the relay ZSP are picked up before the code begins. In that case circuit It?) provides another connection to terminal B in multiple with circuit Ifla which does not interfere with the transmission in any way. It will be seen that when relay 'IP is picked up circuit 26b makes the step short regardless of the condition of circuit 2% and the code is determined solely by ISP, relay 2SP remaining energized to initiate its code after the termination of the code in progress. It is obvious that a similar result occurs on any other step of a code when both characters are available, a short step taking precedence over a long one in each case.

Although relay ISP was picked up over circuit I including the lever contacts, it is held energized independently of these contacts during the transmission of the station selecting steps. This insures that no energized SP relay will be released by lever operation to possibly change the character of an impulse so as to select an undesired station.

When relay ID picks up, (Fig. 1B) at the end of the seventh step, its contact I again inserts circuit I into the connection to terminal C for the stick circuit I5 for relay ISP. Since now the transmission is under the control of relay ISP alone, even though other relays SP are energized, the transmission will be stopped, and a new code initiated, in case a lever of the selected panel is operated during transmission of the function steps. This insures that the controlled device will be operated to a position to correspond with the lever position even though the lever is operated after the step to which the lever is assigned has been transmitted.

Relay ID upon becoming energized also opens the circuit Ifia, releasing OT to close the line to begin the eighth step, and prepares a new transmitting circuit 32 extending from terminal B at contact 0 of relay ESP, over front contact e of relay ID, back contact (2 of relay IZP to contact e of relay I 9P, from which point various branches extend over the front contacts e of relays 8P to HP and contacts of the lever controlled relays IPR, 2G0, 21-10 and 21 R to circuit 23, 26, 21 or 29, and thence through relay OT to terminal C.

The eighth step is controlled by circuit 230 or 210 selected by contact 2) of relay IPR. Since relay IPR has been reversed, the energization of relay 8P prepares circuit 270 at its front contact e, to make the eighth step long.

The apparatus functions on the eighth step in the same manner as on the long fourth step already described, relays A3, B2 and C3 operating in order, the step being terminated upon the release of relay B2.

To insure against incorrect registration of a function step at the field station in the event of a line failure, the character of each function step is not registered at the receiving station until the line is closed to begin the next step. When the line opens at the end of the eighth step, relay 9? at the office and relay 3P at the station pick up and the long character of that step is stored at the station by relay C3 which is held energized over its stick circuit 24b. Relay 9]? upon becoming energized opens circuit 21c and prepares a new circuit 25c for relay OT, to make the ninth step short to correspond with the released position of relay 26C. Relay OT therefore releases and closes the line to begin the ninth step, and then each relay L2 picks up, closing circuit I4 to operate relay Z to the left. At the selected station, relay C3 is still picked up, and relay Z closes the branch I33 of a register circuit I34 prepared by relays D and 3P, which extends from terminal B at resistor 12, Fig. 20, contact a of relay IMP, the winding of relay IWS, contact (1 of relay 3P, contacts 0 of relays D, IR and Z, contact e of relay C3 to terminal C.

tact c in circuit I34.

Relay IWS is energized momentarily over circuit I33 to close its right-hand contacts, energizing the switch control relay IWZ to reverse, to thereby actuate the switch machine ISM in a well-known manner to close and lock the track switch IW in its reverse position.

In a control code having a short eighth step controlled by relay IPR in its normal position, relay A3 will be held energized until the beginning of the ninth step in place of relay C3 and the impulse delivered over circuit I34 to circuit I33 will be in the opposite direction, from terminal B at contact e of relay A3 through relay IWS to terminal C at resistor 13, to cause relay IWS to close its left-hand contacts, as shown.

Relay A2 picks up at the beginning of the ninth step and terminates the step by closing circuit 220, Fig. 1C..

When the line opens at the end of the short ninth step, relay It? at the ofiice and relay 4P at the station pick up and the short character of that step is stored at the station by relay A2 which is held energized over its stick circuit IBa. Relay IIJP upon becoming energized opens circuit 260 and prepares a new circuit 23d for relay OT to make the tenth step short to correspond with the positions of contact (1 of relay 2H0. Relay OT therefore releases and closes the line to begin the tenth step, and then each relay L2 picks up, closing circuit 22 to operate relay Z to the right. At the station, relay A2 is still picked up and relay Z completes a circuit I35, Fig. 2B, for relay 2G8, which has been prepared by relays D and I? and is a branch of circuit I36 extending from contacts d of relays IR, D and 4P through the winding of relay ZGS, back contact of relay IP, to circuit I2I and thence to terminal B at contact b of relay AI.

Since the circuit I36 is now connected over contact 01 of relay Z and contact e of relay A2 to terminal B, both ends of circuit I35 for relay 2G6 are at the same potential and relay 2GS is not operated.

In a signal control code initiated by lever 28G, relay 2GC is picked up in response to the lever operation. and prepares circuit 290 to make the ninth step long, in which case relay C2 will be held energized until the beginning of the tenth step in place of relay A2 and will connect terminal C to circuit I35--I36 to pick up relay 2G8, and relay 2G8 will be held energized over a stick circuit I2Id extending to terminal C at its contact a and to terminal B over circuit I2I. Circuit I2Id will be opened to release relay ZGS when relay IP picks up at the end of the twelfth step.

Relay A3 picks up at the beginning of the tenth step, and in the code being described, terminates the step by closing circuit 23d. Relays L2 then release, relays IIP at the office and relay 5P at the station pick up and the character of that step is stored by relay A3, in the code being described, or by relay C3 if the tenth step is long. Relay IIP upon becoming energized opens circuit 23d and prepares a new circuit 26d for relay OT to make the eleventh step short to correspond with the position of contact e of relay 2l-IC. Relay OT therefore releases and closes the line to begin the eleventh step, and then the line relay L2 picks up, operating the station relay Z to the left to close its con- A branch .I3'I of circuit I33 extends over contact d of relay 5? and contact c of relay 2G8 through the lower winding of the polar stick signal control relay ZLHS to terminal B or C, but this circuit is open at contact c of relay 2GS so that there is no impulse delivered to relay 2LI-IS in this case.

Relay A2 picks up at the beginning of the eleventh step and terminates the step by closing circuit 26d. Relays L2 then release, relays I2P at the oflice and relay 6? at the station pick up and the character of that step is stored by relay A2, in the code being described, or by relay C2 if the eleventh step is long.

Relay I2P upon becoming energized opens circuit 32 at its contact 01 thereby disconnecting terminal B from circuit 23d to release relay OT, and prepares a new circuit 23 for relay OT extending from terminal B over back contacts 1 of relays I5P, MP, I3P and front contact 1 of relay I2P to circuit 23, to make the twelfth step short. Relay OT therefore releases and closes the line to begin the twelfth step, and then each line relay L2 picks up, operating relays Z to the right to prepare circuit I36 to register the character of the eleventh impulse. A branch I38 of this circuit extends over contacts 11 of relays GP and 2G8 through the lower winding of the signal control relay ZRl-IS to terminal B or C, but this circuit is not closed and no impulse is delivered to relay 2RHS in this case. Relay A3 picks up at the beginning of the twelfth step and terminates the step by closing circuit 23 Relays L2 release, and relay I3? is picked up over a branch of circuit 25 including front contact I) of relay I2P. Relay PC is restored to normal at this time, circuit 39 which extends through its upper winding to terminal C being energized by a connection over the branch circuit 39a extending over back contact :1 of relay OR, Fig. 1B, and the normally closed contact of a recall key RC to contact e of relay I 2P and thence over circuit 25 to terminal B. The station relay 'IP is also picked up at this time.

Relay I3P upon becoming energized completes the pick-up circuit 4|] for relay IS from terminal B over contact 0 of relay ISP, contact d of relay ID, the upper winding of relay IS, contact at of relay I3P to terminal C at contact I; of relay OM. Relay IS picks up, reestablishing its stick circuit I, and opening the stick circuit I5-I for relay ISP, which relay releases. Back contact I of relay I3P opens circuit 23 so that relay OT releases to terminate the code.

Since relay PC has been restored to normal, the line circuit is now supplied with current of normal polarity and relay LI picks up at the oflice and at each station in place of relay L2, each closing circuit 8 to pick up relays W and. AI, and opening circuit 24 to deenergize relays X, Y and A3. Relays X open their contacts 0 to release the ofiice relay I3P and. the station relay 'IP. The office relay AI at its back contact b opens circuits 2Ia and 2 I0, releasing relays OM and ID, and the station relay AI opens circuits I2 Ia and I 2 I0, releasing relays IR and D. Relay CR is left reversed, but this is of no moment, because it will be restored to normal upon the closing of circuit II3 at the beginning of the next code.

This completes the restoration of the apparatus to normal. In the event one or more of the relays S at the office or stations is now in its released position, the initiating circuit II! for relay OT or the similar circuit III! for the station transmitter relay T becomes closed as soon as relay AI picks up and relay X releases at the end of a code. It follows that the line circuit is energized by a short positive impulse between each two successive codes.

In response to the control code just described, an indication codewill be initiated at the beginning of the operation of the track switch, upon the release of the normal switch indication relay INWP, to indicate the open or unlocked condition of the switch. This code is also initiated when the switch is opened due to conditions in the field, in which case relay IWK, Fig. 1C, is reversed by the code to light lamp IWE. Since relay lWK has been already reversed by closing circuit 3, the first indication code following a switch control code does not change the condition of the office apparatus. A second code follows, however, when the track switch becomes closed and locked reverse, upon the'energization of the reverse switch indication relay IRWP, as will now be described.

When relay IRWP releases, its contact e momentarily opens the holding circuit liil for the station starting relay S, Fig. 2B, which relay releases. Circuit IOI issimilar to the circuit l for the ofiice starting relay l S and includesin series, contacts e of all relays controlling the character of indications to be transmitted, as will be clear from Fig. 2C. Relay S, at its back contact completes circuit III! to pick up relay T, Fig. 2A, to initiate the code. Relays Ll release, relay PC reverses, and then relay T is energized repeatedly over circuits I23, I26, I21 and I29 which correspond to the ofiice circuits 23, 26, 21 and 29 already described; relays L2 and the relays controlled thereby operate and the code is transmitted and receivedin the same manner as the control code already described, except for those differences now to be pointed out.

At the station, the circuit controlled over front contact 1 of relay IP is a branch 129a of circuit I29, and consequently the first step of an indication code is always long, whereas in a control code, it is always short. When the first impulse is long, relays L2 are held energized until relays C2 pick up and relays B2 release, and at the end of the impulse, relay 2PL is picked up in place of relays ZPS and R, over circuit Rita, in unison with the office relay 2P, and at the sametime, the office relay OR is picked up over a corresponding circuit 30a in place of'relay OM, relay OR being held energized over a stick. circuit 21b until the end of the code.

The arrangement is such as to insure that no interference occurs in the event the office and one or more stations initiate codes at the same time. In that case relay OT makes the first step short, thereby placing the station apparatus in condition to receive the control code, as hereinbefore described.

The second step of an indication code is used for selection between stations so as to prevent any station from sending more than one code in the event another station has a code stored for transmission, as hereinafter explained. In the present instance, assuming that only one station is transmitting, it will be seen that when relay ZPL picks up, it opens circuit [29a at its back contact 1 to release relay T to begin the second step, and prepares a circuit IZ'Ia. for relay T extending to terminal B at back contact 0 of relay S over circuit Hi], to make the second step long. Relay ZPL also controls a circuit l23a. at its contact e over which relay T may be controlled under conditions hereinafter described, to make the second step short, but circuit |23a is not effective in the code being described. The second step therefore is terminated by closing circuit l21a upon the release of relay B2 following the energization of relay C3, and is a long step.

Line relays L2 then release, relays Y operate to the right, and at the station having its relay S released relay M is picked up over a circuit 128!) extending from terminal B over: circuit I28 to the back contact I) of relay SS, front contact 0 of ZPL, back contact I) of relay S, the upper winding of relay M and then over circuit l0! to terminal C at front contact e of relay IMP. Relay M upon becoming energized completes a stick circuit l2lb extending from terminal B over circuit [2| and front contact a, of relay M, back contact b of relay D, the lower winding of relay M to terminal C. Relay M is now controlled like relay ISP in the control code hereinbefore described, for similar reasons. Circuit l2|b corresponds to circuit [5 and holds relay M energized independently of circuit llll until relay D picks up, at which time contact I) of relay D opens circuit IZIb and closes circuit" IZIe extending from terminal B over circuit I21, front contact a of relay M, front contact b of relay D, back contact I) of relay S, through the upper winding of relay M and thence over circuit [0| to terminal C, circuit 1216 holding relay M energized until relay S picks up at the end of the code. The control of relay M over circuit NH insures the initiation of a new code in case one of the indication relays at the station shifts its position during this part of the code.

At the end of the second step, the station relay SP is picked up over contact b of relay 2PL in the'code being described, and then relay 2PL releases, and the operations on the station selecting steps three to seven, inclusive, are the same as on the corresponding steps of the control code except that relay T controls the transmission instead of relay OT. The lengths of these steps is determined by the connections of the various branches of circuit l32a over the contacts e of relays 3P to IR as will be apparent from Fig. 2B.

It is to be understood that the relays S at the various stations release whenever a change occurs in the condition of one of the controlling relays. If during the code being described, relays S at other stations release subsequent to the opening of the pick-up circuit I281) for relay M, which occurs upon the relase of relay 2PL, these stations will be eliminated by station selection, due to the fact that their relays M cannot pick up, and will have no effect upon the code. If, however, any relay S at another station releases prior to the end of the second step, its apparatus will be in the same condition as that at the station being described, its relay T will be operated in unison with the one at that station, and its relay M will pick up as above described. Therefore a plurality of stations may start the third step of the code, but all but the one having the superior code call will be eliminated by station selection, since the code delivered to the line circuit is characteristic of one station only.

At the station having its code call connections arranged as in Fig. 2B, a circuit E2611 is prepared by relay 3P to make the third step short, and the corresponding circuit at another station arranged to make the third step long will be in-- effective. At such other station, the connections from wires I20 and 13!) to contacts b and c of relay 3P will be interchanged, and the energization of circuit I20 which picks up relay 4P at the selected station will at each station connected to receive a long third step complete a branch I4I0; of a circuit MI for a storage relay SS provided relay M at such station is energized. Circuit I4Ia extends from terminal B over circuit I20, contact of relay 3P, back contact 6 of relay D, front contact 0 of relay M, back contact e of relay HIP, relay SS to terminal C. It will be seen that relay SS will pick up at each station having its M relay energized except at the one having the superior code, at the end of one of the sta tion selecting steps, over a branch of circuit Idl including contact 0 of one of the relays 3P to 'IP, inclusive. Each energized relay SS completes a stick circuit IM extending to terminal B over its contact a and back contact d of relay 2PL or back contact I) of relay M, and is released during the transmission of a succeeding indication code. When relay SS picks up on any step the associated relay P fails to pick up, consequently the stepping and transmitting relay operations at the inferior stations are discontinued on one or another of the station selecting steps until finally there is but one station left in control of the line. At the end of the seventh step, the selected relay ID at the omce and the corresponding relay D at the selected station pick up along with relays 2P and ZPS, and relay CR 0perates as in the case of a control code. Relay CR at its right-hand contact a connects terminal B to circuit I321) having various branches completed over contacts 1 of the relays P as shown in Fig. 2C, for controlling relay T to transmit the function steps of the indication code, the character of which is determined in accordance with the positions of contacts 1 of the station relays ITR, etc.

In the code being described, the eighth, ninth and tenth steps will be short, relay T being opcrate-d over branches I230, I260 and I23d of circuit I32b controlled respectively by the detector track relay ITR and by the approach relays ZRAR and ZLAR in their energized positions, as shown. The eighth step is terminated when the station relay A3 picks up to complete circuit I230, and its short character will be stored by the ofiice relay A3 until the beginning of the ninth step, when a branch 33 of circuit 36 is closed momentarily from terminal B at contact 6 of relay A3, Fig. 1A, contact 0 of relay Z, contacts b of relays OR and ID, contact 0 of relay 9P, through the windings of relays ITK and KR, resistor T3 to terminal C, relays ITK and KR being energized in a direction to close their lefthand contacts, as shown.

The ninth step is terminated when the station relay A2 picks up to complete circuit I260 and its short character is stored by the office relay A2, which at the beginning of the tenth step delivers an impulse of normal polarity over circuits 36 and 3'I to relays ZRAK and KR. The short tenth step, controlled over circuit I23d, is similar to the eighth, and at the beginning of the eleventh step relay A3 delivers an impulse of normal polarity over circuits 3d and 38 to relays ZLAK and KR.

In an indication code transmitted while the track relay ITR is released, the eighth step is controlled by circuit I2Ic, Fig. 2C, and is a long step, and the character is stored by relay C3 in place of relay A3 in which case, at the beginning of the ninth step circuit 33 is energized momentarily by an impulse of reverse polarity. Circuit 33 may be traced from terminal B at resistor 12, Fig, 1C, through relays XR and TR over circuit .34 to terminal C at contact 6 of relay C3. Re-

approach indication relays.

lay ITK is a stick polar relay for indicating the condition of the track section It of Fig. 2C, and its contact 0. remains closed to light the track indication lamp ITE. In a similar manner, lamp ZRAE is lighted by the transmission of a long tenth impulse when section Illt is occupied, and lamp ZLAE by the transmission of a long eleventh impulse when section 2t is occupied. Relay XR is a biased polar relay and closes its contact a only for the duration of an impulse of current of reverse polarity supplied to any of the track or The neutral relay TKP which is normally energized over a circuit 43 including the pole-changing contacts b and c of the track and approach indication relays, in series, as shown in Fig. 10, has its polarity reversed upon a change in position of any of these relays, which causes it to momentarily close its back contact a. Consequently when relay ITK, ZRAK or ZLAK operates from normal to reverse, relays XR and TKP close their contacts momentarily to complete a circuit for the bell XB. The sounding of bell XB therefore indicates the entrance of a train upon one of the controlling track sections It, 2t or Hit of Fig. 1C and the bell will be sounded repeatedly on successive steps of the code in case a plurality of the indication relays are operated to reverse on different steps. On the other hand, it will be clear that the bell is not sounded upon the repetition of an existing indication, in which case relay TKP is not operated, nor upon the receipt of a track clear or approach clear indication, in which case relay XR is not operated.

The eleventh step is controlled over circuit I 29d, Fig. 2C, relay INWP being released, and its long character is stored by relay C2 to supply an impulse of reverse polarity over circuit 44 to the upper winding of relay IWK of Fig. 1C. Since relay IPR is now reversed, circuit 44 is open at left-hand contact 0 of relay IPR and the impulse is not delivered.

The twelfth step is controlled over circuit I23e, relay IRWP being energized. The indication code is not terminated with the twelfth step, but relay T is controlled over front contacts f of relays 'IP and HIP to transmit two additional steps to indicate the condition of the sig nals and of the locking relay IMP.

The short character of the twelfth step is stored-by relay A3 which at the beginning of the thirteenth step delivers an impulse of normal polarity over circuits 34 and 45 to the upper winding of relay IWK, which is thereupon operated to the left to extinguish lamp IWE, deenergize relay IPR to lock that relay reversed, and to reenergize relay IWC over the branch of circuit 4 which includes the right-hand contacts 0 of relay IPR and lever ISW. The closing of contact 0 of relay IWC renders lever 25G available for controlling the signals. The thirteenth and fourteenth steps are short, being controlled over circuits IZGe and I237, respectively, and are registered at the oflice by momentarily energizing relays ZHK and ZMK to the left over circuits 46 and 41 at the beginning of the fourteenth and fifteenth steps, respectively.

At the end of the fourteenth step relay S is picked up over circuit MI) extending from terminal B over circuit I25, contacts 0 of relays MP and M, front contact e of relay MP, the upper winding of relay S over circuit I0! to terminal C, reestablishing the holding circuit IQI for relay S from terminal B at contact I of relay IR, resistor rI, contact a and the lower winding of relay S to terminal C at contact eof relay IMP. Subsequently relay MP releases and provides another connection from terminal B to circuit I ill at its back contact d. Relay S opens circuit l2le at its contact I), releasing relay M, and disconnects terminal B from circuit H by opening its back contact 0. Relay M opens the circuit l2I-i32-i32bl23fi23, thereby releasing relay-T to begin the fifteenth step. No further operations of the station relay T occur, the last step of each indication code being a short impulse terminated by the operation of the ofiice relay OT.

At the office, relay IEP picks up over circuit 25 and contact b of relay MP at the end of the fourteenth step, and when relay A2 picks up on the fifteenth step a circuit H1) is closed from terminal B over front contact ,1 of relay ISP to pick up relay OT to terminate the step.

Relay L2 then releases, operating relay Y to the left, opening circuit 25 to deenergize relay IEP and connecting terminal B over circuit l9 to circuit 39 at front contact I) of relay ISP to complete that circuit momentarily to restore relay PC to normal. Relay l5P then releases, opening circuit I'lb to deenergize relay OT. Since relay PC is normal, relays L! now pick up, closing circuit 8 to reenergize relays W and Al and releasing relays X and A2. The relays Al open circuits 2| and I2! for relays M, OR, ID and D which completes the restoration of the apparatus to normal.

It will be evident from the foregoing, that at the end of the indication code just described, there may be a plurality of relays S at other stations which are released to store codes for transmission. Each of these relays will complete its circuit III! to initiate the next code as soon as a short positive impulse has been transmitted. These stations may be divided into two groups, the first comprising those at which relay M picked up at the end of the second step of the preceding code, at each of which relay SS is now energized and relay S is released, and the second comprising those at which relay S released too late to effect the energization of relays M and SS.

Relays M at the stations of the first group are also now released, due to the opening of circuit 17.! b at the end of the preceding code, and although the pick-up circuit l28b for relay M at each of these stations is open at back contact I) of relay SS a new pick-up circuit I280 is prepared, which extends to terminal B at front contact I) of relay SS.

The stations of both groups will transmit the first step in unison, and this will be along step, provided the office transmitter remains inactive, which will be registered by the energization of relay ZPL at the end of the first step, whereupon relay 2PL at its contact 0 will complete circuit I280 to pick up relay M at each station of the first group only, each such relay closing its stick circuit [21b and opening circuit I42 to release relay SS, since contact d of relay 2PL and contact b of relay M are both open. These relays M therefore now pick up at the end of the first step, whereas in the preceding code they picked up at the end of the second step. The branch circuit [23a for relay T is now connected to terminal B over circuits I32a, I32, contact a of relay M and circuit l2! at each station of the first group. These stations therefore cause the code to have a short second step, so that circuit I281) will not be closed at the end of the step, consequently the relays M, and likewise the relays T and SS, at stations of the second group remain deenergized. The stepping operations at all but one station of the first group, and at all stations of the second group, will be discontinued on one or another of the station selecting steps, as in the code already described, while at each inferior station of the first group only, relay SS will pick up when the character of an impulse does not correspond to the station code call, to give that station precedence over any'station of the second group. In this manner, each station of the first group transmits its code in turn, in the order of code superiority.

At the end of this group of codes, conditions are the same as at the beginning of the first indication code; that is, a plurality of relays S may have been released to store codes, but no relay SS is energized. Therefore as soon as the line becomes free these stations initiate a code having a long second step, and transmit their codes in order as a group in which each code except the first has a short second step, as already described.

This feature insures that new code storages cannot delay the transmission of previously stored codes, even though the new codes have superior code calls.

Our apparatus includes a recall feature by which the operator may initiate an indication code from any station withoutcausing a change in the condition of any station device. To do this, he presses one of the control levers'of' the corresponding oflice panel momentarily toinitiate the transmission of a control code to the desired station, holding the recall key RC, Fig. 1B, in its reversed position until the code is completed.

The operation of key RC shifts the control of the restoring circuit 39 for relay PC from relay IZP to relay MP, so that two additional steps will be transmitted, in which case relay PC is restored by an impulse transmitted over circuit 3% at the end of the fourteenth step. Circuit lill for the station starting relay S, Fig. 2B, normally has two connections to terminal B, one at back contact 1 of relay IR and the other at back contact 11 of MP, both of which areopened on the fourteenth step of the recall control code to release relay S, as required.

It is to be noted that our apparatus is so arranged as to minimize the effect of the failure of any relay circuit upon the system as a whole. It has been explained that to produce the intervals between steps, relay T or OT is held energized until the relay P. for the next step picks up over a circuit including a front contact e or f of the relay P for thepreceding step. The latter relay although picked up has just been deenergized by the operation of contact b of relay Y, and will restore the line to the closed condition in case the next P relay fails. In case circuit [8 or 24 fails to close to operate Y to release relay P for the preceding step, relay X in series therewith will release to open the circuit for the P relays at its contact 0 to insure that the line circuit will become closed. The effect of the failure of any of the pick-up circuits for relay T or OT to close will also result in holding the line steadily closed on the corresponding step. In either case, the step will not be terminated upon the release of relay B2 following the energization of relay C2 or C3 as described but an additional relay D2 or D3 at the ofiice will be operated, which in turn will be deenergized by the release of relay C2 or C3 and will release in 

